/****************************************************************
 *																*
 * C++ Vector and Matrix Algebra routines						*
 * Author: Jean-Francois DOUE									*
 * Version 3.1 --- October 1993									*
 *																*
 ****************************************************************/
//
//	From "Graphics Gems IV / Edited by Paul S. Heckbert
//	Academic Press, 1994, ISBN 0-12-336156-9
//	"You are free to use and modify this code in any way
//	you like." (p. xv)
//
//	Modified by J. Nagle, March 1997
//	-	All functions are inline.
//	-	All functions are const-correct.
//	-	All checking is via the standard "assert" macro.
//	-	Stream I/O is disabled for portability, but can be
//		re-enabled by defining ALGEBRA3IOSTREAMS.
//
#ifndef ALGEBRA3H
#define ALGEBRA3H

#include <stdlib.h>
#include <assert.h>
#include <math.h>

#ifndef M_PI
#define M_PI       3.14159265358979323846
#endif

// this line defines a new type: pointer to a function which returns a
// double and takes as argument a double
typedef double (*V_FCT_PTR)(double);

// min-max macros
#define MIN(A,B) ((A) < (B) ? (A) : (B))
#define MAX(A,B) ((A) > (B) ? (A) : (B))
#define CLAMP(V,A,B) (MIN((B), MAX((A), (V))))

#undef min					// allow as function names
#undef max

#define ALGEBRA3IOSTREAMS
#include <iostream>
using namespace std;

// error handling macro
#define ALGEBRA_ERROR(E) { assert(false); }

class vec2;
class vec3;
class vec4;
class mat3;
class mat4;

enum {
    VX, VY, VZ, VW
}; // axes
enum {
    PA, PB, PC, PD
}; // planes
enum {
    RED, GREEN, BLUE
}; // colors
enum {
    KA, KD, KS, ES
}; // phong coefficients
//
//	PI
//
//const double M_PI = (double) 3.14159265358979323846;		// per CRC handbook, 14th. ed.
//const double M_PI_2 = (M_PI/2.0);				// PI/2
//const double M2_PI = (M_PI*2.0);				// PI*2




/****************************************************************
 *																*
 *			    2D Vector										*
 *																*
 ****************************************************************/

class vec2 {
protected:

    double n[2];

public:

    // Constructors

    vec2();
    vec2(const double x, const double y);
    explicit vec2(const double d);
    vec2(const vec2& v); // copy constructor
    vec2(const vec3& v); // cast v3 to v2
    vec2(const vec3& v, int dropAxis); // cast v3 to v2

    // Assignment operators

    vec2& operator =(const vec2& v); // assignment of a vec2
    vec2& operator +=(const vec2& v); // incrementation by a vec2
    vec2& operator -=(const vec2& v); // decrementation by a vec2
    vec2& operator *=(const double d); // multiplication by a constant
    vec2& operator /=(const double d); // division by a constant
    double& operator [](int i); // indexing
    double operator [](int i) const;// read-only indexing

    // special functions

    double length() const; // length of a vec2
    double length2() const; // squared length of a vec2
    vec2& normalize(); // normalize a vec2 in place
    vec2& apply(V_FCT_PTR fct); // apply a func. to each component

    // friends

    friend vec2 operator -(const vec2& v); // -v1
    friend vec2 operator +(const vec2& a, const vec2& b); // v1 + v2
    friend vec2 operator -(const vec2& a, const vec2& b); // v1 - v2
    friend vec2 operator *(const vec2& a, const double d); // v1 * 3.0
    friend vec2 operator *(const double d, const vec2& a); // 3.0 * v1
    friend vec2 operator *(const mat3& a, const vec2& v); // M . v
    friend vec2 operator *(const vec2& v, const mat3& a); // v . M
    friend double operator *(const vec2& a, const vec2& b); // dot product
    friend vec2 operator /(const vec2& a, const double d); // v1 / 3.0
    friend vec3 operator ^(const vec2& a, const vec2& b); // cross product
    friend int operator ==(const vec2& a, const vec2& b); // v1 == v2 ?
    friend int operator !=(const vec2& a, const vec2& b); // v1 != v2 ?

#ifdef ALGEBRA3IOSTREAMS
    friend ostream& operator <<(ostream& s, const vec2& v); // output to stream
    friend istream& operator >>(istream& s, vec2& v); // input from strm.
#endif /* ALGEBRA3IOSTREAMS */

    friend void swap(vec2& a, vec2& b); // swap v1 & v2
    friend vec2 min(const vec2& a, const vec2& b); // min(v1, v2)
    friend vec2 max(const vec2& a, const vec2& b); // max(v1, v2)
    friend vec2 prod(const vec2& a, const vec2& b); // term by term *

    // necessary friend declarations

    friend class vec3;
};

/****************************************************************
 *																*
 *			    3D Vector										*
 *																*
 ****************************************************************/

class vec3 {
protected:

    double n[3];

public:

    // Constructors

    vec3();
    vec3(const double x, const double y, const double z);
    explicit vec3(const double d);
    vec3(const vec3& v); // copy constructor
    vec3(const vec2& v); // cast v2 to v3
    vec3(const vec2& v, double d); // cast v2 to v3
    vec3(const vec4& v); // cast v4 to v3
    vec3(const vec4& v, int dropAxis); // cast v4 to v3

    // Assignment operators

    vec3& operator =(const vec3& v); // assignment of a vec3
    vec3& operator +=(const vec3& v); // incrementation by a vec3
    vec3& operator -=(const vec3& v); // decrementation by a vec3
    vec3& operator *=(const double d); // multiplication by a constant
    vec3& operator /=(const double d); // division by a constant
    double& operator [](int i); // indexing
    double operator[](int i) const; // read-only indexing

    // special functions

    double length() const; // length of a vec3
    double length2() const; // squared length of a vec3
    vec3& normalize(); // normalize a vec3 in place
    vec3& apply(V_FCT_PTR fct); // apply a func. to each component

    // friends

    friend vec3 operator -(const vec3& v); // -v1
    friend vec3 operator +(const vec3& a, const vec3& b); // v1 + v2
    friend vec3 operator -(const vec3& a, const vec3& b); // v1 - v2
    friend vec3 operator *(const vec3& a, const double d); // v1 * 3.0
    friend vec3 operator *(const double d, const vec3& a); // 3.0 * v1
    friend vec3 operator *(const mat4& a, const vec3& v); // M . v
    friend vec3 operator *(const vec3& v, const mat4& a); // v . M
    friend double operator *(const vec3& a, const vec3& b); // dot product
    friend vec3 operator /(const vec3& a, const double d); // v1 / 3.0
    friend vec3 operator ^(const vec3& a, const vec3& b); // cross product
    friend int operator ==(const vec3& a, const vec3& b); // v1 == v2 ?
    friend int operator !=(const vec3& a, const vec3& b); // v1 != v2 ?

#ifdef ALGEBRA3IOSTREAMS
    friend ostream& operator <<(ostream& s, const vec3& v); // output to stream
    friend istream& operator >>(istream& s, vec3& v); // input from strm.
#endif // ALGEBRA3IOSTREAMS
    friend void swap(vec3& a, vec3& b); // swap v1 & v2
    friend vec3 min(const vec3& a, const vec3& b); // min(v1, v2)
    friend vec3 max(const vec3& a, const vec3& b); // max(v1, v2)
    friend vec3 prod(const vec3& a, const vec3& b); // term by term *

    // necessary friend declarations

    friend class vec2;
    friend class vec4;
    friend class mat3;
    friend vec2 operator *(const mat3& a, const vec2& v); // linear transform
    friend vec3 operator *(const mat3& a, const vec3& v);
    friend mat3 operator *(const mat3& a, const mat3& b); // matrix 3 product
};

/****************************************************************
 *																*
 *			    4D Vector										*
 *																*
 ****************************************************************/

class vec4 {
protected:

    double n[4];

public:

    // Constructors

    vec4();
    vec4(const double x, const double y, const double z, const double w);
    explicit vec4(const double d);
    vec4(const vec4& v); // copy constructor
    vec4(const vec3& v); // cast vec3 to vec4
    vec4(const vec3& v, const double d); // cast vec3 to vec4

    // Assignment operators

    vec4& operator =(const vec4& v); // assignment of a vec4
    vec4& operator +=(const vec4& v); // incrementation by a vec4
    vec4& operator -=(const vec4& v); // decrementation by a vec4
    vec4& operator *=(const double d); // multiplication by a constant
    vec4& operator /=(const double d); // division by a constant
    double& operator [](int i); // indexing
    double operator[](int i) const; // read-only indexing

    // special functions

    double length() const; // length of a vec4
    double length2() const; // squared length of a vec4
    vec4& normalize(); // normalize a vec4 in place
    vec4& apply(V_FCT_PTR fct); // apply a func. to each component

    // friends

    friend vec4 operator -(const vec4& v); // -v1
    friend vec4 operator +(const vec4& a, const vec4& b); // v1 + v2
    friend vec4 operator -(const vec4& a, const vec4& b); // v1 - v2
    friend vec4 operator *(const vec4& a, const double d); // v1 * 3.0
    friend vec4 operator *(const double d, const vec4& a); // 3.0 * v1
    friend vec4 operator *(const mat4& a, const vec4& v); // M . v
    friend vec4 operator *(const vec4& v, const mat4& a); // v . M
    friend double operator *(const vec4& a, const vec4& b); // dot product
    friend vec4 operator /(const vec4& a, const double d); // v1 / 3.0
    friend int operator ==(const vec4& a, const vec4& b); // v1 == v2 ?
    friend int operator !=(const vec4& a, const vec4& b); // v1 != v2 ?

#ifdef ALGEBRA3IOSTREAMS
    friend ostream& operator <<(ostream& s, const vec4& v); // output to stream
    friend istream& operator >>(istream& s, vec4& v); // input from strm.
#endif //  ALGEBRA3IOSTREAMS
    friend void swap(vec4& a, vec4& b); // swap v1 & v2
    friend vec4 min(const vec4& a, const vec4& b); // min(v1, v2)
    friend vec4 max(const vec4& a, const vec4& b); // max(v1, v2)
    friend vec4 prod(const vec4& a, const vec4& b); // term by term *

    // necessary friend declarations

    friend class vec3;
    friend class mat4;
    friend vec3 operator *(const mat4& a, const vec3& v); // linear transform
    friend mat4 operator *(const mat4& a, const mat4& b); // matrix 4 product
};

/****************************************************************
 *																*
 *			   3x3 Matrix										*
 *																*
 ****************************************************************/

class mat3 {
protected:

    vec3 v[3];

public:

    // Constructors

    mat3();
    mat3(const vec3& v0, const vec3& v1, const vec3& v2);
    explicit mat3(const double d);
    mat3(const mat3& m);

    // Assignment operators

    mat3& operator =(const mat3& m); // assignment of a mat3
    mat3& operator +=(const mat3& m); // incrementation by a mat3
    mat3& operator -=(const mat3& m); // decrementation by a mat3
    mat3& operator *=(const double d); // multiplication by a constant
    mat3& operator /=(const double d); // division by a constant
    vec3& operator [](int i); // indexing
    const vec3& operator [](int i) const; // read-only indexing

    // special functions

    mat3 transpose() const; // transpose
    mat3 inverse() const; // inverse
    mat3& apply(V_FCT_PTR fct); // apply a func. to each element

    // friends

    friend mat3 operator -(const mat3& a); // -m1
    friend mat3 operator +(const mat3& a, const mat3& b); // m1 + m2
    friend mat3 operator -(const mat3& a, const mat3& b); // m1 - m2
    friend mat3 operator *(const mat3& a, const mat3& b); // m1 * m2
    friend mat3 operator *(const mat3& a, const double d); // m1 * 3.0
    friend mat3 operator *(const double d, const mat3& a); // 3.0 * m1
    friend mat3 operator /(const mat3& a, const double d); // m1 / 3.0
    friend int operator ==(const mat3& a, const mat3& b); // m1 == m2 ?
    friend int operator !=(const mat3& a, const mat3& b); // m1 != m2 ?

#ifdef ALGEBRA3IOSTREAMS
    friend ostream& operator <<(ostream& s, const mat3& m); // output to stream
    friend istream& operator >>(istream& s, mat3& m); // input from strm.
#endif //  ALGEBRA3IOSTREAMS
    friend void swap(mat3& a, mat3& b); // swap m1 & m2

    // necessary friend declarations

    friend vec3 operator *(const mat3& a, const vec3& v); // linear transform
    friend vec2 operator *(const mat3& a, const vec2& v); // linear transform
};

/****************************************************************
 *																*
 *			   4x4 Matrix										*
 *																*
 ****************************************************************/

class mat4 {
protected:

    vec4 v[4];

public:

    // Constructors

    mat4();
    mat4(const vec4& v0, const vec4& v1, const vec4& v2, const vec4& v3);
    explicit mat4(const double d);
    mat4(const mat4& m);

    // Assignment operators

    mat4& operator =(const mat4& m); // assignment of a mat4
    mat4& operator +=(const mat4& m); // incrementation by a mat4
    mat4& operator -=(const mat4& m); // decrementation by a mat4
    mat4& operator *=(const double d); // multiplication by a constant
    mat4& operator /=(const double d); // division by a constant
    vec4& operator [](int i); // indexing
    const vec4& operator [](int i) const; // read-only indexing

    // special functions

    mat4 transpose() const; // transpose
    mat4 inverse() const; // inverse
    mat4& apply(V_FCT_PTR fct); // apply a func. to each element

    // friends

    friend mat4 operator -(const mat4& a); // -m1
    friend mat4 operator +(const mat4& a, const mat4& b); // m1 + m2
    friend mat4 operator -(const mat4& a, const mat4& b); // m1 - m2
    friend mat4 operator *(const mat4& a, const mat4& b); // m1 * m2
    friend mat4 operator *(const mat4& a, const double d); // m1 * 4.0
    friend mat4 operator *(const double d, const mat4& a); // 4.0 * m1
    friend mat4 operator /(const mat4& a, const double d); // m1 / 3.0
    friend int operator ==(const mat4& a, const mat4& b); // m1 == m2 ?
    friend int operator !=(const mat4& a, const mat4& b); // m1 != m2 ?

#ifdef ALGEBRA3IOSTREAMS
    friend ostream& operator <<(ostream& s, const mat4& m); // output to stream
    friend istream& operator >>(istream& s, mat4& m); // input from strm.
#endif //  ALGEBRA3IOSTREAMS
    friend void swap(mat4& a, mat4& b); // swap m1 & m2

    // necessary friend declarations

    friend vec4 operator *(const mat4& a, const vec4& v); // linear transform
    friend vec3 operator *(const mat4& a, const vec3& v); // linear transform
};

/****************************************************************
 *																*
 *			    Quaternion										*
 *																*
 ****************************************************************/
class quat {
protected:
    double a;
    vec3 v;

public:
    quat() : a(1.0), v(0.0) {}
    quat(vec3 v) : a(0.0), v(v) {}
    quat(double a, vec3 v) : a(a), v(v) {}
    static quat axisAngle(vec3 axis, double angle) {
        double axisLen = axis.length();
        if (axisLen < .00000000001)
            return quat(1,vec3(0,0,0));
        axis.normalize(); 
        return quat(cos(angle*.5), sin(angle*.5)*axis);
    }
    static quat getRotation(vec3 dir1, vec3 dir2) {
        dir1.normalize(); dir2.normalize();
        vec3 axis = dir1^dir2;
        double sina = axis.length();
        double cosa = dir1*dir2;
        double angle = atan2(sina,cosa);
        return axisAngle(axis, angle);
    }
    double &operator[](int i) { if (i==0) return a; else return v[i-1]; }
    quat nlerp(const quat &q, double t) { // normalized lerp
        quat i((1-t)*a+t*q.a, (1-t)*v+t*q.v);
        i.normalize();
        return i;
    }
    vec3 rotate(vec3 v) {
        quat pq(v);
        quat qinv = conjugate();
        quat res = (*this)*pq*qinv;
        return res.v;
    }
    quat getNearest(const quat &q) {
        if (q.a*a+q.v*v < 0)
            return quat(-a,-v);
        else
            return *this;
    }
    quat operator*(const quat &q) const {
        return quat(a*q.a-v*q.v, (a*q.v)+(q.a*v)+(v^q.v));
    }
    quat conjugate() { // aka inverse
        return quat(a, -v);
    }
    quat& normalize() { // normalize in-place
        double invlen = 1.0/sqrt(a*a+v*v);
        a *= invlen;
        v *= invlen;
        return *this;
    }
    double angle() const { return 2.0 * atan2(a, v.length()); }
    vec3 axis() const { return v; }
};


/****************************************************************
 *																*
 *	       2D functions and 3D functions						*
 *																*
 ****************************************************************/

mat3 identity2D(); // identity 2D
mat3 translation2D(const vec2& v); // translation 2D
mat3 rotation2D(const vec2& Center, const double angleDeg); // rotation 2D
mat3 scaling2D(const vec2& scaleVector); // scaling 2D
mat4 identity3D(); // identity 3D
mat4 translation3D(const vec3& v); // translation 3D
mat4 rotation3D(vec3 Axis, const double angleDeg);// rotation 3D
mat4 scaling3D(const vec3& scaleVector); // scaling 3D
mat4 perspective3D(const double d); // perspective 3D

//
//	Implementation
//

/****************************************************************
 *																*
 *		    vec2 Member functions								*
 *																*
 ****************************************************************/

// CONSTRUCTORS

inline vec2::vec2() {
}

inline vec2::vec2(const double x, const double y) {
    n[VX] = x;
    n[VY] = y;
}

inline vec2::vec2(const double d) {
    n[VX] = n[VY] = d;
}

inline vec2::vec2(const vec2& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
}

inline vec2::vec2(const vec3& v) // it is up to caller to avoid divide-by-zero
{
    n[VX] = v.n[VX] / v.n[VZ];
    n[VY] = v.n[VY] / v.n[VZ];
}
;

inline vec2::vec2(const vec3& v, int dropAxis) {
    switch (dropAxis) {
    case VX:
        n[VX] = v.n[VY];
        n[VY] = v.n[VZ];
        break;
    case VY:
        n[VX] = v.n[VX];
        n[VY] = v.n[VZ];
        break;
    default:
        n[VX] = v.n[VX];
        n[VY] = v.n[VY];
        break;
    }
}

// ASSIGNMENT OPERATORS

inline vec2& vec2::operator =(const vec2& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    return *this;
}

inline vec2& vec2::operator +=(const vec2& v) {
    n[VX] += v.n[VX];
    n[VY] += v.n[VY];
    return *this;
}

inline vec2& vec2::operator -=(const vec2& v) {
    n[VX] -= v.n[VX];
    n[VY] -= v.n[VY];
    return *this;
}

inline vec2& vec2::operator *=(const double d) {
    n[VX] *= d;
    n[VY] *= d;
    return *this;
}

inline vec2& vec2::operator /=(const double d) {
    double d_inv = 1. / d;
    n[VX] *= d_inv;
    n[VY] *= d_inv;
    return *this;
}

inline double& vec2::operator [](int i) {
    assert(!(i < VX || i> VY)); // subscript check
    return n[i];
}

inline double vec2::operator [](int i) const {
    assert(!(i < VX || i> VY));
    return n[i];
}

// SPECIAL FUNCTIONS

inline double vec2::length() const {
    return sqrt(length2());
}

inline double vec2::length2() const {
    return n[VX] * n[VX] + n[VY] * n[VY];
}

inline vec2& vec2::normalize() // it is up to caller to avoid divide-by-zero
{
    *this /= length();
    return *this;
}

inline vec2& vec2::apply(V_FCT_PTR fct) {
    n[VX] = (*fct)(n[VX]);
    n[VY] = (*fct)(n[VY]);
    return *this;
}

// FRIENDS

inline vec2 operator -(const vec2& a) {
    return vec2(-a.n[VX], -a.n[VY]);
}

inline vec2 operator +(const vec2& a, const vec2& b) {
    return vec2(a.n[VX] + b.n[VX], a.n[VY] + b.n[VY]);
}

inline vec2 operator -(const vec2& a, const vec2& b) {
    return vec2(a.n[VX] - b.n[VX], a.n[VY] - b.n[VY]);
}

inline vec2 operator *(const vec2& a, const double d) {
    return vec2(d * a.n[VX], d * a.n[VY]);
}

inline vec2 operator *(const double d, const vec2& a) {
    return a * d;
}

inline vec2 operator *(const mat3& a, const vec2& v) {
    vec3 av;

    av.n[VX] = a.v[0].n[VX] * v.n[VX] + a.v[0].n[VY] * v.n[VY] + a.v[0].n[VZ];
    av.n[VY] = a.v[1].n[VX] * v.n[VX] + a.v[1].n[VY] * v.n[VY] + a.v[1].n[VZ];
    av.n[VZ] = a.v[2].n[VX] * v.n[VX] + a.v[2].n[VY] * v.n[VY] + a.v[2].n[VZ];
    return av;
}

inline vec2 operator *(const vec2& v, const mat3& a) {
    return a.transpose() * v;
}

inline double operator *(const vec2& a, const vec2& b) {
    return (a.n[VX] * b.n[VX] + a.n[VY] * b.n[VY]);
}

inline vec2 operator /(const vec2& a, const double d) {
    double d_inv = 1. / d;
    return vec2(a.n[VX] * d_inv, a.n[VY] * d_inv);
}

inline vec3 operator ^(const vec2& a, const vec2& b) {
    return vec3(0.0, 0.0, a.n[VX] * b.n[VY] - b.n[VX] * a.n[VY]);
}

inline int operator ==(const vec2& a, const vec2& b) {
    return (a.n[VX] == b.n[VX]) && (a.n[VY] == b.n[VY]);
}

inline int operator !=(const vec2& a, const vec2& b) {
    return !(a == b);
}

#ifdef ALGEBRA3IOSTREAMS
inline ostream& operator <<(ostream& s, const vec2& v) {
    return s << "| " << v.n[VX] << ' ' << v.n[VY] << " |";
}
inline istream& operator >>(istream& s, vec2& v) {
    vec2 v_tmp;
    char c = ' ';

    while (isspace(c))
        s >> c;
    // The vectors can be formatted either as x y or | x y |
    if (c == '|') {
        s >> v_tmp[VX] >> v_tmp[VY];
        while (s >> c && isspace(c))
            ;
        if (c != '|')
            s.setstate(ios::badbit);
    } else {
        s.putback(c);
        s >> v_tmp[VX] >> v_tmp[VY];
    }
    if (s)
        v = v_tmp;
    return s;
}
#endif // ALGEBRA3IOSTREAMS
inline void swap(vec2& a, vec2& b) {
    vec2 tmp(a);
    a = b;
    b = tmp;
}

inline vec2 min(const vec2& a, const vec2& b) {
    return vec2(MIN(a.n[VX], b.n[VX]), MIN(a.n[VY], b.n[VY]));}

inline vec2 max(const vec2& a, const vec2& b) {
    return vec2(MAX(a.n[VX], b.n[VX]), MAX(a.n[VY], b.n[VY]));}

inline vec2 prod(const vec2& a, const vec2& b) {
    return vec2(a.n[VX] * b.n[VX], a.n[VY] * b.n[VY]);
}

/****************************************************************
 *																*
 *		    vec3 Member functions								*
 *																*
 ****************************************************************/

// CONSTRUCTORS

inline vec3::vec3() {
}

inline vec3::vec3(const double x, const double y, const double z) {
    n[VX] = x;
    n[VY] = y;
    n[VZ] = z;
}

inline vec3::vec3(const double d) {
    n[VX] = n[VY] = n[VZ] = d;
}

inline vec3::vec3(const vec3& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
}

inline vec3::vec3(const vec2& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = 1.0;
}

inline vec3::vec3(const vec2& v, double d) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = d;
}

inline vec3::vec3(const vec4& v) // it is up to caller to avoid divide-by-zero
{
    n[VX] = v.n[VX] / v.n[VW];
    n[VY] = v.n[VY] / v.n[VW];
    n[VZ] = v.n[VZ] / v.n[VW];
}

inline vec3::vec3(const vec4& v, int dropAxis) {
    switch (dropAxis) {
    case VX:
        n[VX] = v.n[VY];
        n[VY] = v.n[VZ];
        n[VZ] = v.n[VW];
        break;
    case VY:
        n[VX] = v.n[VX];
        n[VY] = v.n[VZ];
        n[VZ] = v.n[VW];
        break;
    case VZ:
        n[VX] = v.n[VX];
        n[VY] = v.n[VY];
        n[VZ] = v.n[VW];
        break;
    default:
        n[VX] = v.n[VX];
        n[VY] = v.n[VY];
        n[VZ] = v.n[VZ];
        break;
    }
}

// ASSIGNMENT OPERATORS

inline vec3& vec3::operator =(const vec3& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
    return *this;
}

inline vec3& vec3::operator +=(const vec3& v) {
    n[VX] += v.n[VX];
    n[VY] += v.n[VY];
    n[VZ] += v.n[VZ];
    return *this;
}

inline vec3& vec3::operator -=(const vec3& v) {
    n[VX] -= v.n[VX];
    n[VY] -= v.n[VY];
    n[VZ] -= v.n[VZ];
    return *this;
}

inline vec3& vec3::operator *=(const double d) {
    n[VX] *= d;
    n[VY] *= d;
    n[VZ] *= d;
    return *this;
}

inline vec3& vec3::operator /=(const double d) {
    double d_inv = 1. / d;
    n[VX] *= d_inv;
    n[VY] *= d_inv;
    n[VZ] *= d_inv;
    return *this;
}

inline double& vec3::operator [](int i) {
    assert(! (i < VX || i> VZ));
    return n[i];
}

inline double vec3::operator [](int i) const {
    assert(! (i < VX || i> VZ));
    return n[i];
}

// SPECIAL FUNCTIONS

inline double vec3::length() const {
    return sqrt(length2());
}

inline double vec3::length2() const {
    return n[VX] * n[VX] + n[VY] * n[VY] + n[VZ] * n[VZ];
}

inline vec3& vec3::normalize() // it is up to caller to avoid divide-by-zero
{
    *this /= length();
    return *this;
}

inline vec3& vec3::apply(V_FCT_PTR fct) {
    n[VX] = (*fct)(n[VX]);
    n[VY] = (*fct)(n[VY]);
    n[VZ] = (*fct)(n[VZ]);
    return *this;
}

// FRIENDS

inline vec3 operator -(const vec3& a) {
    return vec3(-a.n[VX], -a.n[VY], -a.n[VZ]);
}

inline vec3 operator +(const vec3& a, const vec3& b) {
    return vec3(a.n[VX] + b.n[VX], a.n[VY] + b.n[VY], a.n[VZ] + b.n[VZ]);
}

inline vec3 operator -(const vec3& a, const vec3& b) {
    return vec3(a.n[VX] - b.n[VX], a.n[VY] - b.n[VY], a.n[VZ] - b.n[VZ]);
}

inline vec3 operator *(const vec3& a, const double d) {
    return vec3(d * a.n[VX], d * a.n[VY], d * a.n[VZ]);
}

inline vec3 operator *(const double d, const vec3& a) {
    return a * d;
}

inline vec3 operator *(const mat3& a, const vec3& v) {
#define ROWCOL(i) a.v[i].n[0]*v.n[VX] + a.v[i].n[1]*v.n[VY] \
    + a.v[i].n[2]*v.n[VZ]
    return vec3(ROWCOL(0),ROWCOL(1), ROWCOL(2));
#undef ROWCOL // (i)
}

inline vec3 operator *(const mat4& a, const vec3& v) {
    return a * vec4(v);
}

inline vec3 operator *(const vec3& v, const mat4& a) {
    return a.transpose() * v;
}

inline double operator *(const vec3& a, const vec3& b) {
    return (a.n[VX] * b.n[VX] + a.n[VY] * b.n[VY] + a.n[VZ] * b.n[VZ]);
}

inline vec3 operator /(const vec3& a, const double d) {
    double d_inv = 1. / d;
    return vec3(a.n[VX] * d_inv, a.n[VY] * d_inv, a.n[VZ] * d_inv);
}

inline vec3 operator ^(const vec3& a, const vec3& b) {
    return vec3(a.n[VY] * b.n[VZ] - a.n[VZ] * b.n[VY], a.n[VZ] * b.n[VX]
            - a.n[VX] * b.n[VZ], a.n[VX] * b.n[VY] - a.n[VY] * b.n[VX]);
}

inline int operator ==(const vec3& a, const vec3& b) {
    return (a.n[VX] == b.n[VX]) && (a.n[VY] == b.n[VY]) && (a.n[VZ] == b.n[VZ]);
}

inline int operator !=(const vec3& a, const vec3& b) {
    return !(a == b);
}

#ifdef ALGEBRA3IOSTREAMS
inline ostream& operator <<(ostream& s, const vec3& v) {
    return s << "| " << v.n[VX] << ' ' << v.n[VY] << ' ' << v.n[VZ] << " |";
}

inline istream& operator >>(istream& s, vec3& v) {
    vec3 v_tmp;
    char c = ' ';

    while (isspace(c))
        s >> c;
    // The vectors can be formatted either as x y z or | x y z |
    if (c == '|') {
        s >> v_tmp[VX] >> v_tmp[VY] >> v_tmp[VZ];
        while (s >> c && isspace(c))
            ;
        if (c != '|')
            s.setstate(ios::badbit);
    } else {
        s.putback(c);
        s >> v_tmp[VX] >> v_tmp[VY] >> v_tmp[VZ];
    }
    if (s)
        v = v_tmp;
    return s;
}
#endif // ALGEBRA3IOSTREAMS
inline void swap(vec3& a, vec3& b) {
    vec3 tmp(a);
    a = b;
    b = tmp;
}

inline vec3 min(const vec3& a, const vec3& b) {
    return vec3(MIN(a.n[VX], b.n[VX]), MIN(a.n[VY], b.n[VY]), MIN(a.n[VZ],
            b.n[VZ]));}

inline vec3 max(const vec3& a, const vec3& b) {
    return vec3(MAX(a.n[VX], b.n[VX]), MAX(a.n[VY], b.n[VY]), MAX(a.n[VZ],
            b.n[VZ]));}

inline vec3 prod(const vec3& a, const vec3& b) {
    return vec3(a.n[VX] * b.n[VX], a.n[VY] * b.n[VY], a.n[VZ] * b.n[VZ]);
}

/****************************************************************
 *																*
 *		    vec4 Member functions								*
 *																*
 ****************************************************************/

// CONSTRUCTORS

inline vec4::vec4() {
}

inline vec4::vec4(const double x, const double y, const double z,
        const double w) {
    n[VX] = x;
    n[VY] = y;
    n[VZ] = z;
    n[VW] = w;
}

inline vec4::vec4(const double d) {
    n[VX] = n[VY] = n[VZ] = n[VW] = d;
}

inline vec4::vec4(const vec4& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
    n[VW] = v.n[VW];
}

inline vec4::vec4(const vec3& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
    n[VW] = 1.0;
}

inline vec4::vec4(const vec3& v, const double d) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
    n[VW] = d;
}

// ASSIGNMENT OPERATORS

inline vec4& vec4::operator =(const vec4& v) {
    n[VX] = v.n[VX];
    n[VY] = v.n[VY];
    n[VZ] = v.n[VZ];
    n[VW] = v.n[VW];
    return *this;
}

inline vec4& vec4::operator +=(const vec4& v) {
    n[VX] += v.n[VX];
    n[VY] += v.n[VY];
    n[VZ] += v.n[VZ];
    n[VW] += v.n[VW];
    return *this;
}

inline vec4& vec4::operator -=(const vec4& v) {
    n[VX] -= v.n[VX];
    n[VY] -= v.n[VY];
    n[VZ] -= v.n[VZ];
    n[VW] -= v.n[VW];
    return *this;
}

inline vec4& vec4::operator *=(const double d) {
    n[VX] *= d;
    n[VY] *= d;
    n[VZ] *= d;
    n[VW] *= d;
    return *this;
}

inline vec4& vec4::operator /=(const double d) {
    double d_inv = 1. / d;
    n[VX] *= d_inv;
    n[VY] *= d_inv;
    n[VZ] *= d_inv;
    n[VW] *= d_inv;
    return *this;
}

inline double& vec4::operator [](int i) {
    assert(! (i < VX || i> VW));
    return n[i];
}

inline double vec4::operator [](int i) const {
    assert(! (i < VX || i> VW));
    return n[i];
}

// SPECIAL FUNCTIONS

inline double vec4::length() const {
    return sqrt(length2());
}

inline double vec4::length2() const {
    return n[VX] * n[VX] + n[VY] * n[VY] + n[VZ] * n[VZ] + n[VW] * n[VW];
}

inline vec4& vec4::normalize() // it is up to caller to avoid divide-by-zero
{
    *this /= length();
    return *this;
}

inline vec4& vec4::apply(V_FCT_PTR fct) {
    n[VX] = (*fct)(n[VX]);
    n[VY] = (*fct)(n[VY]);
    n[VZ] = (*fct)(n[VZ]);
    n[VW] = (*fct)(n[VW]);
    return *this;
}

// FRIENDS

inline vec4 operator -(const vec4& a) {
    return vec4(-a.n[VX], -a.n[VY], -a.n[VZ], -a.n[VW]);
}

inline vec4 operator +(const vec4& a, const vec4& b) {
    return vec4(a.n[VX] + b.n[VX], a.n[VY] + b.n[VY], a.n[VZ] + b.n[VZ],
            a.n[VW] + b.n[VW]);
}

inline vec4 operator -(const vec4& a, const vec4& b) {
    return vec4(a.n[VX] - b.n[VX], a.n[VY] - b.n[VY], a.n[VZ] - b.n[VZ],
            a.n[VW] - b.n[VW]);
}

inline vec4 operator *(const vec4& a, const double d) {
    return vec4(d * a.n[VX], d * a.n[VY], d * a.n[VZ], d * a.n[VW]);
}

inline vec4 operator *(const double d, const vec4& a) {
    return a * d;
}

inline vec4 operator *(const mat4& a, const vec4& v) {
#define ROWCOL(i) a.v[i].n[0]*v.n[VX] + a.v[i].n[1]*v.n[VY] \
    + a.v[i].n[2]*v.n[VZ] + a.v[i].n[3]*v.n[VW]
    return vec4(ROWCOL(0),ROWCOL(1), ROWCOL(2),ROWCOL(3));
#undef ROWCOL // (i)
}

inline vec4 operator *(const vec4& v, const mat4& a) {
    return a.transpose() * v;
}

inline double operator *(const vec4& a, const vec4& b) {
    return (a.n[VX] * b.n[VX] + a.n[VY] * b.n[VY] + a.n[VZ] * b.n[VZ] + a.n[VW]
            * b.n[VW]);
}

inline vec4 operator /(const vec4& a, const double d) {
    double d_inv = 1. / d;
    return vec4(a.n[VX] * d_inv, a.n[VY] * d_inv, a.n[VZ] * d_inv, a.n[VW]
            * d_inv);
}

inline int operator ==(const vec4& a, const vec4& b) {
    return (a.n[VX] == b.n[VX]) && (a.n[VY] == b.n[VY]) && (a.n[VZ] == b.n[VZ])
            && (a.n[VW] == b.n[VW]);
}

inline int operator !=(const vec4& a, const vec4& b) {
    return !(a == b);
}

#ifdef ALGEBRA3IOSTREAMS
inline ostream& operator <<(ostream& s, const vec4& v) {
    return s << "| " << v.n[VX] << ' ' << v.n[VY] << ' ' << v.n[VZ] << ' '
            << v.n[VW] << " |";
}

inline istream& operator >>(istream& s, vec4& v) {
    vec4 v_tmp;
    char c = ' ';

    while (isspace(c))
        s >> c;
    // The vectors can be formatted either as x y z w or | x y z w |
    if (c == '|') {
        s >> v_tmp[VX] >> v_tmp[VY] >> v_tmp[VZ] >> v_tmp[VW];
        while (s >> c && isspace(c))
            ;
        if (c != '|')
            s.setstate(ios::badbit);
    } else {
        s.putback(c);
        s >> v_tmp[VX] >> v_tmp[VY] >> v_tmp[VZ] >> v_tmp[VW];
    }
    if (s)
        v = v_tmp;
    return s;
}
#endif // ALGEBRA3IOSTREAMS
inline void swap(vec4& a, vec4& b) {
    vec4 tmp(a);
    a = b;
    b = tmp;
}

inline vec4 min(const vec4& a, const vec4& b) {
    return vec4(MIN(a.n[VX], b.n[VX]), MIN(a.n[VY], b.n[VY]), MIN(a.n[VZ],
            b.n[VZ]), MIN(a.n[VW], b.n[VW]));}

inline vec4 max(const vec4& a, const vec4& b) {
    return vec4(MAX(a.n[VX], b.n[VX]), MAX(a.n[VY], b.n[VY]), MAX(a.n[VZ],
            b.n[VZ]), MAX(a.n[VW], b.n[VW]));}

inline vec4 prod(const vec4& a, const vec4& b) {
    return vec4(a.n[VX] * b.n[VX], a.n[VY] * b.n[VY], a.n[VZ] * b.n[VZ],
            a.n[VW] * b.n[VW]);
}

/****************************************************************
 *																*
 *		    mat3 member functions								*
 *																*
 ****************************************************************/

// CONSTRUCTORS

inline mat3::mat3() {
}

inline mat3::mat3(const vec3& v0, const vec3& v1, const vec3& v2) {
    v[0] = v0;
    v[1] = v1;
    v[2] = v2;
}

inline mat3::mat3(const double d) {
    v[0] = v[1] = v[2] = vec3(d);
}

inline mat3::mat3(const mat3& m) {
    v[0] = m.v[0];
    v[1] = m.v[1];
    v[2] = m.v[2];
}

// ASSIGNMENT OPERATORS

inline mat3& mat3::operator =(const mat3& m) {
    v[0] = m.v[0];
    v[1] = m.v[1];
    v[2] = m.v[2];
    return *this;
}

inline mat3& mat3::operator +=(const mat3& m) {
    v[0] += m.v[0];
    v[1] += m.v[1];
    v[2] += m.v[2];
    return *this;
}

inline mat3& mat3::operator -=(const mat3& m) {
    v[0] -= m.v[0];
    v[1] -= m.v[1];
    v[2] -= m.v[2];
    return *this;
}

inline mat3& mat3::operator *=(const double d) {
    v[0] *= d;
    v[1] *= d;
    v[2] *= d;
    return *this;
}

inline mat3& mat3::operator /=(const double d) {
    v[0] /= d;
    v[1] /= d;
    v[2] /= d;
    return *this;
}

inline vec3& mat3::operator [](int i) {
    assert(! (i < VX || i> VZ));
    return v[i];
}

inline const vec3& mat3::operator [](int i) const {
    assert(!(i < VX || i> VZ));
    return v[i];
}

// SPECIAL FUNCTIONS

inline mat3 mat3::transpose() const {
    return mat3(vec3(v[0][0], v[1][0], v[2][0]),
            vec3(v[0][1], v[1][1], v[2][1]), vec3(v[0][2], v[1][2], v[2][2]));
}

inline mat3 mat3::inverse() const // Gauss-Jordan elimination with partial pivoting
{
    mat3 a(*this), // As a evolves from original mat into identity
            b(identity2D()); // b evolves from identity into inverse(a)
    int i, j, i1;

    // Loop over cols of a from left to right, eliminating above and below diag
    for (j = 0; j < 3; j++) { // Find largest pivot in column j among rows j..2
        i1 = j; // Row with largest pivot candidate
        for (i = j + 1; i < 3; i++)
            if (fabs(a.v[i].n[j]) > fabs(a.v[i1].n[j]))
                i1 = i;

        // Swap rows i1 and j in a and b to put pivot on diagonal
        swap(a.v[i1], a.v[j]);
        swap(b.v[i1], b.v[j]);

        // Scale row j to have a unit diagonal
        if (a.v[j].n[j] == 0.)ALGEBRA_ERROR("mat3::inverse: singular matrix; can't invert\n")
        b.v[j] /= a.v[j].n[j];
        a.v[j] /= a.v[j].n[j];

        // Eliminate off-diagonal elems in col j of a, doing identical ops to b
        for (i = 0; i < 3; i++)
            if (i != j) {
                b.v[i] -= a.v[i].n[j] * b.v[j];
                a.v[i] -= a.v[i].n[j] * a.v[j];
            }
    }
    return b;
}

inline mat3& mat3::apply(V_FCT_PTR fct) {
    v[VX].apply(fct);
    v[VY].apply(fct);
    v[VZ].apply(fct);
    return *this;
}

// FRIENDS

inline mat3 operator -(const mat3& a) {
    return mat3(-a.v[0], -a.v[1], -a.v[2]);
}

inline mat3 operator +(const mat3& a, const mat3& b) {
    return mat3(a.v[0] + b.v[0], a.v[1] + b.v[1], a.v[2] + b.v[2]);
}

inline mat3 operator -(const mat3& a, const mat3& b) {
    return mat3(a.v[0] - b.v[0], a.v[1] - b.v[1], a.v[2] - b.v[2]);
}

inline mat3 operator *(const mat3& a, const mat3& b) {
#define ROWCOL(i, j) \
    a.v[i].n[0]*b.v[0][j] + a.v[i].n[1]*b.v[1][j] + a.v[i].n[2]*b.v[2][j]
    return mat3(vec3(ROWCOL(0,0),ROWCOL(0,1), ROWCOL(0,2)), vec3(ROWCOL(1,0),ROWCOL(1,1), ROWCOL(1,2)), vec3(ROWCOL(2,0),ROWCOL(2,1), ROWCOL(2,2)));
#undef ROWCOL // (i, j)
}

inline mat3 operator *(const mat3& a, const double d) {
    return mat3(a.v[0] * d, a.v[1] * d, a.v[2] * d);
}

inline mat3 operator *(const double d, const mat3& a) {
    return a * d;
}

inline mat3 operator /(const mat3& a, const double d) {
    return mat3(a.v[0] / d, a.v[1] / d, a.v[2] / d);
}

inline int operator ==(const mat3& a, const mat3& b) {
    return (a.v[0] == b.v[0]) && (a.v[1] == b.v[1]) && (a.v[2] == b.v[2]);
}

inline int operator !=(const mat3& a, const mat3& b) {
    return !(a == b);
}

#ifdef ALGEBRA3IOSTREAMS
inline ostream& operator <<(ostream& s, const mat3& m) {
    return s << m.v[VX] << '\n' << m.v[VY] << '\n' << m.v[VZ];
}

inline istream& operator >>(istream& s, mat3& m) {
    mat3 m_tmp;

    s >> m_tmp[VX] >> m_tmp[VY] >> m_tmp[VZ];
    if (s)
        m = m_tmp;
    return s;
}
#endif // ALGEBRA3IOSTREAMS
inline void swap(mat3& a, mat3& b) {
    mat3 tmp(a);
    a = b;
    b = tmp;
}

/****************************************************************
 *																*
 *		    mat4 member functions								*
 *																*
 ****************************************************************/

// CONSTRUCTORS

inline mat4::mat4() {
}

inline mat4::mat4(const vec4& v0, const vec4& v1, const vec4& v2,
        const vec4& v3) {
    v[0] = v0;
    v[1] = v1;
    v[2] = v2;
    v[3] = v3;
}

inline mat4::mat4(const double d) {
    v[0] = v[1] = v[2] = v[3] = vec4(d);
}

inline mat4::mat4(const mat4& m) {
    v[0] = m.v[0];
    v[1] = m.v[1];
    v[2] = m.v[2];
    v[3] = m.v[3];
}

// ASSIGNMENT OPERATORS

inline mat4& mat4::operator =(const mat4& m) {
    v[0] = m.v[0];
    v[1] = m.v[1];
    v[2] = m.v[2];
    v[3] = m.v[3];
    return *this;
}

inline mat4& mat4::operator +=(const mat4& m) {
    v[0] += m.v[0];
    v[1] += m.v[1];
    v[2] += m.v[2];
    v[3] += m.v[3];
    return *this;
}

inline mat4& mat4::operator -=(const mat4& m) {
    v[0] -= m.v[0];
    v[1] -= m.v[1];
    v[2] -= m.v[2];
    v[3] -= m.v[3];
    return *this;
}

inline mat4& mat4::operator *=(const double d) {
    v[0] *= d;
    v[1] *= d;
    v[2] *= d;
    v[3] *= d;
    return *this;
}

inline mat4& mat4::operator /=(const double d) {
    v[0] /= d;
    v[1] /= d;
    v[2] /= d;
    v[3] /= d;
    return *this;
}

inline vec4& mat4::operator [](int i) {
    assert(! (i < VX || i> VW));
    return v[i];
}

inline const vec4& mat4::operator [](int i) const {
    assert(! (i < VX || i> VW));
    return v[i];
}

// SPECIAL FUNCTIONS;

inline mat4 mat4::transpose() const {
    return mat4(vec4(v[0][0], v[1][0], v[2][0], v[3][0]), vec4(v[0][1],
            v[1][1], v[2][1], v[3][1]),
            vec4(v[0][2], v[1][2], v[2][2], v[3][2]), vec4(v[0][3], v[1][3],
                    v[2][3], v[3][3]));
}

inline mat4 mat4::inverse() const // Gauss-Jordan elimination with partial pivoting
{
    mat4 a(*this), // As a evolves from original mat into identity
            b(identity3D()); // b evolves from identity into inverse(a)
    int i, j, i1;

    // Loop over cols of a from left to right, eliminating above and below diag
    for (j = 0; j < 4; j++) { // Find largest pivot in column j among rows j..3
        i1 = j; // Row with largest pivot candidate
        for (i = j + 1; i < 4; i++)
            if (fabs(a.v[i].n[j]) > fabs(a.v[i1].n[j]))
                i1 = i;

        // Swap rows i1 and j in a and b to put pivot on diagonal
        swap(a.v[i1], a.v[j]);
        swap(b.v[i1], b.v[j]);

        // Scale row j to have a unit diagonal
        if (a.v[j].n[j] == 0.)ALGEBRA_ERROR("mat4::inverse: singular matrix; can't invert\n");
        b.v[j] /= a.v[j].n[j];
        a.v[j] /= a.v[j].n[j];

        // Eliminate off-diagonal elems in col j of a, doing identical ops to b
        for (i = 0; i < 4; i++)
            if (i != j) {
                b.v[i] -= a.v[i].n[j] * b.v[j];
                a.v[i] -= a.v[i].n[j] * a.v[j];
            }
    }
    return b;
}

inline mat4& mat4::apply(V_FCT_PTR fct) {
    v[VX].apply(fct);
    v[VY].apply(fct);
    v[VZ].apply(fct);
    v[VW].apply(fct);
    return *this;
}

// FRIENDS

inline mat4 operator -(const mat4& a) {
    return mat4(-a.v[0], -a.v[1], -a.v[2], -a.v[3]);
}

inline mat4 operator +(const mat4& a, const mat4& b) {
    return mat4(a.v[0] + b.v[0], a.v[1] + b.v[1], a.v[2] + b.v[2], a.v[3]
            + b.v[3]);
}

inline mat4 operator -(const mat4& a, const mat4& b) {
    return mat4(a.v[0] - b.v[0], a.v[1] - b.v[1], a.v[2] - b.v[2], a.v[3]
            - b.v[3]);
}

inline mat4 operator *(const mat4& a, const mat4& b) {
#define ROWCOL(i, j) a.v[i].n[0]*b.v[0][j] + a.v[i].n[1]*b.v[1][j] + \
    a.v[i].n[2]*b.v[2][j] + a.v[i].n[3]*b.v[3][j]
    return mat4(vec4(ROWCOL(0,0),ROWCOL(0,1), ROWCOL(0,2),ROWCOL(0,3)), vec4(ROWCOL(1,0),ROWCOL(1,1), ROWCOL(1,2),ROWCOL(1,3)), vec4(ROWCOL(2,0),ROWCOL(2,1), ROWCOL(2,2),ROWCOL(2,3)), vec4(ROWCOL(3,0),ROWCOL(3,1), ROWCOL(3,2),ROWCOL(3,3)));
#undef ROWCOL
}

inline mat4 operator *(const mat4& a, const double d) {
    return mat4(a.v[0] * d, a.v[1] * d, a.v[2] * d, a.v[3] * d);
}

inline mat4 operator *(const double d, const mat4& a) {
    return a * d;
}

inline mat4 operator /(const mat4& a, const double d) {
    return mat4(a.v[0] / d, a.v[1] / d, a.v[2] / d, a.v[3] / d);
}

inline int operator ==(const mat4& a, const mat4& b) {
    return ((a.v[0] == b.v[0]) && (a.v[1] == b.v[1]) && (a.v[2] == b.v[2])
            && (a.v[3] == b.v[3]));
}

inline int operator !=(const mat4& a, const mat4& b) {
    return !(a == b);
}

#ifdef ALGEBRA3IOSTREAMS
inline ostream& operator <<(ostream& s, const mat4& m) {
    return s << m.v[VX] << '\n' << m.v[VY] << '\n' << m.v[VZ] << '\n'
            << m.v[VW];
}

inline istream& operator >>(istream& s, mat4& m) {
    mat4 m_tmp;

    s >> m_tmp[VX] >> m_tmp[VY] >> m_tmp[VZ] >> m_tmp[VW];
    if (s)
        m = m_tmp;
    return s;
}
#endif // ALGEBRA3IOSTREAMS
inline void swap(mat4& a, mat4& b) {
    mat4 tmp(a);
    a = b;
    b = tmp;
}

/****************************************************************
 *																*
 *	      			 Mathematica Functions          			*
 *																*
 ****************************************************************/
inline mat3 List(vec3 v0, vec3 v1, vec3 v2) { return mat3(v0, v1, v2); }
inline vec3 List(double s0, double s1, double s2) { return vec3(s0, s1, s2); }
//inline double Abs(double value) { return abs(value); }
inline double Power(double value, double exp) { return pow(value, exp); }
inline double Sqrt(double value) { return sqrt(value); }

/****************************************************************
 *																*
 *	       2D functions and 3D functions						*
 *																*
 ****************************************************************/

inline mat3 identity2D() {
    return mat3(vec3(1.0, 0.0, 0.0), vec3(0.0, 1.0, 0.0), vec3(0.0, 0.0, 1.0));
}

inline mat3 translation2D(const vec2& v) {
    return mat3(vec3(1.0, 0.0, v[VX]), vec3(0.0, 1.0, v[VY]), vec3(0.0, 0.0,
            1.0));
}

inline mat3 rotation2D(const vec2& Center, const double angleDeg) {
    double angleRad = angleDeg * M_PI / 180.0, c = cos(angleRad), s = sin(
            angleRad);

    return mat3(vec3(c, -s, Center[VX] * (1.0 - c) + Center[VY] * s), vec3(s,
            c, Center[VY] * (1.0 - c) - Center[VX] * s), vec3(0.0, 0.0, 1.0));
}

inline mat3 scaling2D(const vec2& scaleVector) {
    return mat3(vec3(scaleVector[VX], 0.0, 0.0),
            vec3(0.0, scaleVector[VY], 0.0), vec3(0.0, 0.0, 1.0));
}

inline mat4 identity3D() {
    return mat4(vec4(1.0, 0.0, 0.0, 0.0), vec4(0.0, 1.0, 0.0, 0.0), vec4(0.0,
            0.0, 1.0, 0.0), vec4(0.0, 0.0, 0.0, 1.0));
}

inline mat4 translation3D(const vec3& v) {
    return mat4(vec4(1.0, 0.0, 0.0, v[VX]), vec4(0.0, 1.0, 0.0, v[VY]), vec4(
            0.0, 0.0, 1.0, v[VZ]), vec4(0.0, 0.0, 0.0, 1.0));
}

inline mat4 rotation3D(vec3 Axis, const double angleDeg) {
    double angleRad = angleDeg * M_PI / 180.0, c = cos(angleRad), s = sin(
            angleRad), t = 1.0 - c;

    Axis.normalize();
    return mat4(vec4(t * Axis[VX] * Axis[VX] + c, t * Axis[VX] * Axis[VY] - s
            * Axis[VZ], t * Axis[VX] * Axis[VZ] + s * Axis[VY], 0.0), vec4(t
            * Axis[VX] * Axis[VY] + s * Axis[VZ], t * Axis[VY] * Axis[VY] + c,
            t * Axis[VY] * Axis[VZ] - s * Axis[VX], 0.0), vec4(t * Axis[VX]
            * Axis[VZ] - s * Axis[VY], t * Axis[VY] * Axis[VZ] + s * Axis[VX],
            t * Axis[VZ] * Axis[VZ] + c, 0.0), vec4(0.0, 0.0, 0.0, 1.0));
}

inline mat4 scaling3D(const vec3& scaleVector) {
    return mat4(vec4(scaleVector[VX], 0.0, 0.0, 0.0), vec4(0.0,
            scaleVector[VY], 0.0, 0.0), vec4(0.0, 0.0, scaleVector[VZ], 0.0),
            vec4(0.0, 0.0, 0.0, 1.0));
}

inline mat4 perspective3D(const double d) {
    return mat4(vec4(1.0, 0.0, 0.0, 0.0), vec4(0.0, 1.0, 0.0, 0.0), vec4(0.0,
            0.0, 1.0, 0.0), vec4(0.0, 0.0, 1.0 / d, 0.0));
}

#endif // ALGEBRA3H
